Screen
A screen includes: a screen substrate; a first area disposed on the screen substrate and containing a first main line which has a plurality of first concaves for reflecting light and a first supplementary line which is disposed on the screen substrate at a position adjacent to the first main line and has the same number of second concaves as that of the first concaves formed adjacent to the second concaves, the first main line and the first supplementary line being alternately and repeatedly arranged; and a second area disposed on the screen substrate in a region where an angle of incidence of projection light with respect to the screen substrate becomes larger than in the first area and containing a second main line which has a plurality of third concaves for reflecting light and a second supplementary line which is disposed on the screen substrate at a position adjacent to the second main line and has a larger number of fourth concaves as that of the third concaves formed adjacent to the fourth concaves, the second main line and the second supplementary line being alternately and repeatedly arranged.
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1. Technical Field
The present invention relates to a screen which reflects projection light obliquely supplied from a projection device such as a projector for display of a projection image.
2. Related Art
An example of a known projection image reflecting screen which reflects light obliquely supplied from below to display an image such that the image can be viewed on the front surface side of the screen has a number of concaves or convexes on a screen substrate (for example, see JP-A-2009-15195). This screen has a reflection surface for reflecting projection light on a surface of each concave or convex in correspondence with the position of the projection supplied from a projection device such as a projector. In addition, the directions of the concaves or convexes provided on the screen substrate and disposed adjacent to one another in the vertical direction deviate from the horizontal direction of the screen substrate, which allows reflection of a large quantity of light obliquely supplied from below.
According to the screen disclosed in JP-A-2009-15195, however, a part of the projection light is blocked by projections formed by the adjoining concaves when the angle formed by the projection light from the projector and the screen normal line (angle of incidence) becomes a certain angle or larger. In this case, there is a possibility that loss of view in the image such as local light reduction is produced.
SUMMARYIt is an advantage of some aspects of the invention to provide a screen capable of reducing the possibility of blocking projection light and capable of decreasing loss of view.
A screen according to an aspect of the invention includes: a screen substrate; a first area disposed on the screen substrate and containing a first main line which has a plurality of first concaves for reflecting light and a first supplementary line which is disposed on the screen substrate at a position adjacent to the first main line and has the same number of second concaves as that of the first concaves formed adjacent to the second concaves, the first main line and the first supplementary line being alternately and repeatedly arranged; and a second area disposed on the screen substrate in a region where an angle of incidence of projection light with respect to the screen substrate becomes larger than in the first area and containing a second main line which has a plurality of third concaves for reflecting light and a second supplementary line which is disposed on the screen substrate at a position adjacent to the second main line and has a larger number of fourth concaves as that of the third concaves formed adjacent to the fourth concaves, the second main line and the second supplementary line being alternately and repeatedly arranged.
According to this screen, the first and second supplementary lines are provided as well as the first and second main lines. Thus, even when the angle of incidence of the projection light is large, a sufficient amount of the projection light can be supplied to the surfaces of the first and third concaves for reflection. Moreover, since the number of the fourth concaves on the second supplementary line is larger than the number of the third concaves on the second main line in the second area where the angle of incidence becomes relatively large, each height of projections formed by the third concave and the fourth concave adjacent to the third concave or the fourth concave and by a pair of the fourth concaves adjacent to each other becomes smaller than each height of the corresponding projections in the structure including the same number of the fourth concaves as that of the third concaves similarly to the first area. Thus, even when the angle of incidence of the projection light is larger in the second area than in the first area, the projection light is prevented from being blocked by the projections. Accordingly, loss of view can be reduced.
In a specific aspect of the invention, a reflection portion is formed at least on a part of each surface of the first concaves and the third concaves to reflect the projection light by the reflection portion to the front surface side. The portion other than the part having the reflection portion on each surface of the first concaves and the third concaves and each surface of the second concaves and the fourth concaves absorb or transmit the projection light. The portion other than the part having the reflection portion on each of the first concaves and the third concaves which reflects the projection light to the front surface side and each of the second concaves and the fourth concaves, i.e., the portions not intending to receive the projection light absorb the outside light or the like, for example, to improve the contrast of an image reflected by the screen.
In another aspect of the invention, at least a part of each of the first main line, the first supplementary line, the second main line, and the second supplementary line has a circular-arc shape. Since the first main line, the first supplementary line, the second main line, and the second supplementary line are circular-arc-shaped, the arrangements and shapes of the concaves contained in these lines can be matched with the entrance positions of the projection light. Thus, the projection light can be reflected in an adequate condition. It is preferable that the respective lines are alternately disposed on the screen substrate with no clearance left between one another.
In still another aspect of the invention, in the second area close to the boundary between the second area and the first area, the distance between at least a pair of the fourth concaves adjacent to the same third concave increases as the angle of incidence of the projection light with respect to the screen substrate becomes larger. Since the distance between the fourth concaves adjacent to each other in the second area close to the boundary between the second area and the first area gradually increases as the positions of the fourth concaves shift away from the first area, unevenness in switching in the boundary between the first area and the second area is not produced. It is assumed herein that the single third concave and at least a pair of the fourth concaves disposed for the corresponding third concave on the entrance side of the projection light are considered as a unit. The unevenness in switching herein refers to light unevenness observed as stepped or moiré pattern due to non-uniform change of apparent reflectance caused by different arrangements of the concaves in the two areas.
In yet another aspect of the invention, the number of the fourth concaves contained in the second supplementary line in the second area close to the boundary between the second area and the first area increases as the angle of incidence of the projection light with respect to the screen substrate becomes larger. Since the number of the fourth concaves in the second area close to the boundary between the second area and the first area gradually increases as the positions of the fourth concaves shift away from the first area, unevenness in switching in the boundary between the first area and the second area is not produced.
In still yet another aspect of the invention, the clearance between the first main line and the first supplementary line and the clearance between the second main line and the second supplementary line increase as the angle of incidence of the projection light with respect to the screen substrate becomes larger. In this case, the visibility angle can be secured even when the angle of incidence of the projection light with respect to the screen substrate is large.
In further another aspect of the invention, the screen further includes a third area disposed on the screen substrate in a region where the angle of incidence of the projection light with respect to the screen substrate becomes smaller than in the first area and containing a third main line which has a plurality of fifth concaves and reflects light by at least a part of each of the fifth concaves. In this case, the projection light can be efficiently reflected in the region where the angle of incidence of the projection light is small.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
A screen according to a first embodiment of the invention is hereinafter described with reference to the drawings. In the respective figures, a Z axis corresponds to the normal line direction of a screen 1, a Y axis corresponds to the vertical direction crossing the Z axis at right angles and extending in parallel with the screen 1, and an X axis corresponds to the horizontal direction crossing the Z axis at right angles and extending in parallel with the screen 1.
As illustrated in
The screen 1 includes a screen substrate 4 as a support body, and a surface portion 3 having a plurality of concaves 20 (see
The screen substrate 4 is a sheet-shaped component made of materials containing light absorbing material. The light absorbing material is black polyvinyl chloride, black PET (polyethylene terephthalate) or the like, which allows the screen substrate 4 to absorb outside light OL and others.
The surface portion 3 is a layered portion having a base material constituted by the same light absorbing material as that of the screen substrate 4. The surface portion 3 is provided throughout a surface 4a of the screen substrate 4 in the form of a skin, and is divided into sections of a first area AR1, a second area AR2, and a third area AR3. The first area AR1, the second area AR2, and the third area AR3 are provided in correspondence with the ranges of angles of incidence θ1, θ2, and θ3 (θ3<θ1<θ2) of the projection light PL with respect to the screen substrate 4, and are successively disposed such that the projection position of the projection light PL changes from the third area AR3 to the first area AR1 and further to the second area AR2 as the angle of incidence increases from θ3 to θ1 and further to θ2. Since the first through third areas AR1 through AR3 are provided in correspondence with the angles of incidence θ1, θ2, and θ3, the boundaries between the respective areas AR1, AR2, and AR3 have circular-arc shapes. It is assumed herein that the angles of incidence θ1, θ2, and θ3 are angles formed by the normal line of a plane extending along the screen substrate 4 and the beam of the projection light PL.
Each of the first area AR1, the second area AR2, and the third area AR3 has minute concave and convex structure on a surface (projection surface) 3a considering the angles of incidence θ1, θ2, and θ3 of the projection light PL. That is, the plural concaves 20 provided in the respective areas have different shapes and different arrangements for each of the three areas AR1, AR2, and AR3. For example, the minute concave and convex structure as the arrangement condition of the concaves 20 gradually changes in accordance with the successively changeable angles of incidence θ1 and θ2 in the first and second areas AR1 and AR2 so as to secure view in each part of the screen 1 (secure a condition not containing loss of pixels as viewed from an observer). In addition, since the arrangement condition of the concaves 20 gradually changes in the first area AR1, unevenness in switching between the first area AR1 and the third area AR3 is not produced. A transition area ARx having modified minute concave and convex structure as the arrangement condition of the concaves 20 is provided in the second area AR2 in the vicinity of the boundary between the second area AR2 and the first area AR1 so as to reduce unevenness in switching between the areas AR2 and AR1.
Each of the concaves 20 provided in each of the first area AR1, the second area AR2, and the third area AR3 basically has a spherical surface having substantially the same curvature (see
As can be seen from
The first area AR1 has the first main lines Lm1 and the first supplementary lines Ls1 alternately and repeatedly disposed in a direction crossing the line arrangement directions. Each of the first main lines Lm1 is paired with the first supplementary line Ls1 positioned adjacent to the corresponding first main line Lm1 on the surface portion 3 on the entrance side of the projection light PL (i.e., on the projector 2 side and approximately on the −Y axis direction side). As illustrated in
The clearance between the paired lines Lm1 and Ls1 as the unit UN, and the interval between the first main lines Lm1 and Lm1 with the first supplementary line Ls1 sandwiched therebetween, i.e., the pitch of the first main lines Lm1 are now explained with reference to
In the area AR1, the clearance h1 is set at zero in a region close to the boundary between the area AR1 and the third area AR3 (a region where the angle of incidence θ1 is smaller), and the clearance between the paired lines Lm1 and Ls1 and the pitch of the first main lines Lm1 gradually become larger as the position shifts away from the third area AR3. This structure prevents unevenness in switching between the first area AR1 and the third area AR3.
The circular-arc curves along which the first main lines Lm1 and the first supplementary lines Ls1 are disposed (the arrangement lines R1, R3, and R5) are not limited to “circular” shapes but may “elliptic” shapes, “freely curved” shapes, or combinations of these shapes. In addition, the arrangement lines R1, R3, and R5 may be combinations of straight lines and curves constituting the “elliptic” shapes or the “freely curved” shapes.
Reflection films RS formed on the first concaves 20a are now explained with reference to
As can be seen from
The second area AR2 is now described. As illustrated in
As can be seen from
Similarly, a center distance x4 between each adjoining pair of the fourth concaves 20d on each of the second supplementary lines Ls2 is substantially uniform. In fact, the third and fourth concaves 20c and 20d are disposed along the arrangement lines R3 and R4 with no clearance left between one another as illustrated in
The second area AR2 has the second main lines Lm2 and the second supplementary lines Ls2 alternately and repeatedly disposed in a direction crossing the line arrangement directions. Each of the second main lines Lm2 is paired with the second supplementary line Ls2 positioned adjacent to the corresponding second main line Lm2 on the surface portion 3 on the entrance side of the projection light PL (i.e., on the projector 2 side and approximately on the −Y axis direction side). As illustrated in
The clearance between the paired lines Lm2 and Ls2, and the interval of the second main lines Lm2 and Lm2 with the second supplementary line Ls2 sandwiched therebetween, i.e., the pitch of the second main lines Lm2 are now explained with reference to
The reflection films RS formed on the third concaves 20c are now explained with reference to
As can be seen from
According to this structure, the first main lines Lm1 in the first area AR1 and the second main lines Lm2 in the second area AR2 are disposed such that the relation of the clearances h1<h2<h3<4 holds as illustrated in
As can be seen from
A manufacturing method of the screen 1 is now explained. Initially, in the screen 1, manufacture of a base sheet forming the screen substrate 4 and the surface portion 3 is discussed. The base sheet is made of a material chiefly containing black polyvinyl chloride capable of absorbing light, for example. More specifically, the surface of a sheet made of polyvinyl chloride is heated and softened, and then concaves and convexes are formed by press working using a mold having concave and convex shapes corresponding to the shape of a number of the concaves 20, for example. As a result, a number of minute concave and convex shapes corresponding to the concaves 20 (20a, 20b, 20c, 20d, and 20e) are formed on the base sheet of the screen 1. The sheet made of polyvinyl chloride may contain glass fibers or the like to increase the strength.
Next, a manufacture step of the reflection films RS formed on the first, third, and fifth concaves 20a, 20c, and 20e on the base sheet of the screen 1 is explained. In this step, a film forming device which forms films by vacuum deposition is used for forming the reflection films RS, for example. The material used for forming the films is aluminum or the like. The base sheet of the screen 1 is fixed at a predetermined height along the inner wall surface of a cylindrical vacuum container included in the film forming device. The film forming device heats and evaporates the material of the films in the vacuum container, and deposits the reflection films RS on the first, third, and fifth concaves 20a, 20c, and 20e. The film forming device has an evaporation source in the vacuum container in the same direction as the supply direction of the projection light PL to the screen 1. By this arrangement, the reflection films RS can be obliquely deposited in a direction inclined to the base sheet in correspondence with the projection light PL, and thus can be formed at appropriate positions on the first, third, and fifth concaves 20a, 20c, and 20e.
The base sheet forming the screen substrate 4 and the surface portion 3 may be a sheet-shaped base material chiefly containing transparent PET (polyethylene terephthalate) or the like having light transmissibility with light absorbing black ink applied to the back surface of the base material.
According to this method, the concaves 20 overlap with one another, and thus a projection is produced between each adjoining pair of the concaves 20. More specifically, in the first area AR1, a projection 31 is formed at the corner between the first concaves 20a and the second concaves 20b in each adjoining pair of the units UN as illustrated in
The relationship between the concaves 20 and the projection light PL is now described.
According to the screen 1 in this embodiment, the first and second supplementary lines Ls1 and Ls2 are provided as well as the first and second main lines Lm1 and Lm2. Thus, even when the angle of incidence of the projection light PL with respect to the screen 1 is large, a sufficient amount of the projection light PL can be supplied to the reflection films RS formed on the first and third concaves 20a and 20c. Moreover, since the number of the fourth concaves 20d on each of the second supplementary lines Ls2 is larger than the number of the third concaves 20c on each of the second main lines Lm2, each height of the projections 32 in the second area AR2 becomes smaller than each height of the projections 31 in the first area AR1. Thus, even when the angle of incidence of the projection light PL with respect to the screen 1 is larger in the second area AR2 than in the first area AR1, the projection light PL is prevented from being blocked by the projections 32. Accordingly, loss of view can be reduced.
According to this embodiment, the distance between the adjoining pair of the fourth concaves 20d adjacent to the third concaves 20c within the one unit UN in the transition area ARx gradually increases as the position of the unit UN shifts away from the first area AR1. Thus, the arrangement of the concaves 20 in the first area AR1 can gradually change to the different arrangement of the concaves 20 in the second area AR2. Accordingly, unevenness in switching caused by the change from the first area AR1 to the second area AR2 is not produced in the display of the image reflected by the portion of the boundary between the first area AR1 and the second area AR2.
Second EmbodimentIn the transition area ARx, the number of the fourth concaves 20d corresponding to the third concave 20c within the one unit UN is not uniform. As illustrated in
According to the screen 1 in this embodiment, the number of the fourth concaves 20d on each of the second supplementary lines Ls2 in the transition area ARx gradually increases as the positions of the fourth concaves 20d shift away from the first area AR1. Thus, unevenness in switching caused by the change from the first area AR1 to the second area AR2 in the boundary between the first area AR1 and the second area AR2 can be reduced.
It is not intended that the invention is limited to the respective embodiments described and depicted herein. For example, the arrangements and ranges of the first area AR1, the second area AR2, and the third area AR3 are not limited to those shown in
While a pair of the fourth concaves 20d correspond to the single third concave 20c in the second area AR2 in the embodiments, the number of the fourth concaves 20d may be three or larger, or numerals other than integers such as 2.5 and 3.5. In case of the structure including four or a larger number of the fourth concaves 20d corresponding to the single third concave 20c, only the same advantages as those described above can be offered by the second supplementary lines Ls2, and the arrangement of the fourth concaves 20d and the like in the transition area ARx is difficult to be controlled.
While the reflection films RS are made of aluminum as the film forming material, the reflection films RS may be formed by silver or dielectric multilayer films other than aluminum, for example. When the reflection films RS are metal films, protection films can be further provided on the metal films.
According to the embodiments, the surface of the surface portion 3 may be activated before the reflection films RS are formed on the first, third, and fifth concaves 20a, 20c, and 20e. The surface of the surface portion 3 can be activated by reverse sputtering, plasma discharge, corona discharge, RF bombardment, atmospheric plasma, or other processing. When the surface of the surface portion 3 is activated by an appropriate manner, the adhesiveness and durability of the reflection films RS can be improved.
The third area AR3 provided in the embodiments may be eliminated as long as the first and second areas AR1 and AR2 are disposed in such positions and ranges as to efficiently reflect the projection light PL received from the projector 2 in view of the whole screen 1.
The entire disclosure of Japanese Patent Application No:2009-218619, filed Sep. 24, 2009 is expressly incorporated by reference herein.
Claims
1. A screen comprising:
- a screen substrate;
- a first area disposed on the screen substrate and containing a first main line which has a plurality of first concaves for reflecting light and a first supplementary line which is disposed on the screen substrate at a position adjacent to the first main line and has the same number of second concaves as that of the first concaves formed adjacent to the second concaves, the first main line and the first supplementary line being alternately and repeatedly arranged; and
- a second area disposed on the screen substrate in a region where an angle of incidence of projection light with respect to the screen substrate becomes larger than in the first area and containing a second main line which has a plurality of third concaves for reflecting light and a second supplementary line which is disposed on the screen substrate at a position adjacent to the second main line and has a larger number of fourth concaves as that of the third concaves formed adjacent to the fourth concaves, the second main line and the second supplementary line being alternately and repeatedly arranged.
2. The screen according to claim 1, wherein:
- a reflection portion is formed at least on a part of each surface of the first concaves and the third concaves to reflect the projection light by the reflection portion to the front surface side; and
- the portion other than the part having the reflection portion on each surface of the first concaves and the third concaves and each surface of the second concaves and the fourth concaves absorb or transmit the projection light.
3. The screen according to claim 1, wherein at least a part of each of the first main line, the first supplementary line, the second main line, and the second supplementary line has a circular-arc shape.
4. The screen according to claim 1, wherein the distance between at least a pair of the fourth concaves contained in the second supplementary line and disposed adjacent to the single third concave contained in the second main line in the second area close to the boundary between the second area and the first area increases as the angle of incidence of the projection light with respect to the screen substrate becomes larger.
5. The screen according to claim 1, wherein the number of the fourth concaves contained in the second supplementary line in the second area close to the boundary between the second area and the first area increases as the angle of incidence of the projection light with respect to the screen substrate becomes larger.
6. The screen according to claim 1, wherein the clearance between the first main line and the first supplementary line and the clearance between the second main line and the second supplementary line increase as the angle of incidence of the projection light with respect to the screen substrate becomes larger.
7. The screen according to claim 1, further comprising a third area disposed on the screen substrate in a region where the angle of incidence of the projection light with respect to the screen substrate becomes smaller than in the first area and containing a third main line which has a plurality of fifth concaves and reflects light by at least a part of each of the fifth concaves.
8. The screen according to claim 7, wherein the first concaves, second concaves, third concaves, fourth concaves and the fifth concaves have a spherical surface having substantially the same curvature.
20100259818 | October 14, 2010 | Mikoshiba |
2009-015195 | January 2009 | JP |
Type: Grant
Filed: Sep 7, 2010
Date of Patent: Mar 22, 2011
Assignee: Seiko Epson Corporation (Tokyo)
Inventors: Ryoji Katsuma (Matsumoto), Akira Shinbo (Shiojiri)
Primary Examiner: Christopher Mahoney
Attorney: AdvantEdge Law Group, LLC
Application Number: 12/876,627
International Classification: G03B 21/60 (20060101);